Gownaris Natasha J, Boersma P Dee
Environmental Studies Gettysburg College Gettysburg PA USA.
Department of Biology University of Washington Seattle WA USA.
Ecol Evol. 2021 Mar 13;11(9):4339-4352. doi: 10.1002/ece3.7331. eCollection 2021 May.
Growing animals should allocate their limited resources in ways that maximize survival. Seabird chicks must balance the growth of features and fat reserves needed to survive on land with those needed to successfully fledge and survive at sea. We used a large, 34-year dataset to examine energy allocation in Magellanic penguin chicks. Based on the temporal trends in the selective pressures that chicks faced, we developed predictions relating to the timing of skeletal feature growth (Prediction 1), variation in skeletal feature size and shape (Prediction 2), and responses to periods of high energetic constraint (Prediction 3). We tested our predictions using descriptive statistics, generalized additive models, and principal component analysis. Nearly all of our predictions were supported. Chicks grew their feet first, then their flippers. They continued to grow their bill after fledging (Prediction 1). Variance in feature size increased in young chicks but declined before fledging; this variance was largely driven by overall size rather than by shape (Prediction 2). Chicks that died grew slower and varied more in feature size than those that fledged (Prediction 2). Skeletal features grew rapidly prior to thermoregulation and feet and flippers were 90% grown prior to juvenile feather growth; both thermoregulation and feather growth are energetically expensive (Prediction 3). To avoid starvation, chicks prioritized storing mass during the first 10 days after hatching; then, the body condition of chicks began to decline (Prediction 3). In contrast to our prediction of mass prioritization in young chicks, chicks that were relatively light for their age had high skeletal size to mass ratios. Chicks did not show evidence of reaching physiological growth limits (Prediction 3). By examining energy allocation patterns at fine temporal scales and in the context of detailed natural history data, we provide insight into the trade-offs faced by growing animals.
正在生长的动物应以能使生存几率最大化的方式分配其有限的资源。海鸟雏鸟必须在陆地生存所需的身体特征生长与脂肪储备增长之间取得平衡,同时还要兼顾成功离巢并在海上生存所需的条件。我们利用一个长达34年的大型数据集,研究了麦哲伦企鹅雏鸟的能量分配情况。根据雏鸟所面临的选择压力的时间趋势,我们得出了与骨骼特征生长时间(预测1)、骨骼特征大小和形状的变化(预测2)以及对高能约束期的反应(预测3)相关的预测。我们使用描述性统计、广义相加模型和主成分分析对这些预测进行了检验。几乎所有预测都得到了支持。雏鸟先长脚,然后是鳍状肢。离巢后它们的喙仍在继续生长(预测1)。雏鸟幼小时特征大小的差异增加,但在离巢前减小;这种差异主要由整体大小而非形状驱动(预测2)。死亡的雏鸟比成功离巢的雏鸟生长得更慢,特征大小的变化也更大(预测2)。在体温调节之前,骨骼特征迅速生长,在幼鸟羽毛生长之前,脚和鳍状肢已生长了90%;体温调节和羽毛生长都消耗大量能量(预测3)。为避免饥饿,雏鸟在孵化后的头10天优先储存体重;然后,雏鸟的身体状况开始下降(预测3)。与我们关于雏鸟优先储存体重的预测相反,年龄相对较轻但体重较轻的雏鸟骨骼大小与体重的比率较高。雏鸟没有表现出达到生理生长极限的迹象(预测3)。通过在精细的时间尺度上并结合详细的自然史数据来研究能量分配模式,我们深入了解了正在生长的动物所面临的权衡取舍。
